Telegraph hub circuit repeater



Jan. 30, 1951 w, R 2,539,551

TELEGRAPH HUB cmcun REPEATER Filed Sept. so; 1948 2 Sheets-Sheet 1 FIG.

REPEAT'ER 3 lNl/ENTOR m 77 REA 5V j M.

ATTORNF Patented Jan. 30, 1951 TELEGRAPH HUB CIRCUIT REPEATER Wilton T. Rea, Manhasset, N. Y., assignor to Bell Telephone Laboratories,

Incorporated, New

York, N. Y., a corporation of New York Application September 30, 1948, Serial No. 52,071

7 Claims. 1

This invention relates to hub telegraph repeaters and more particularly to less expensive hub telegraph repeaters which may serve either with or without a multiway regenerator.

An object of the invention is the improvement of hub-type telegraph repeaters. Hub telegraph repeaters are well known in the art. Such repeaters of a type which are not arranged for multiway regeneration are described for instance in Patent 2,056,277 issued to F. S. Kinkead et a1. October 3, 1936, and in Patent 2,069,224 issued to G. C. Cummings February 2, 1937. Hub repeaters arranged for multiway regeneration are described in Patents 2,337,496 and 2,392,339 issued to W. T. Rea on December 21, 1943, and January 3, 1946, respectively. The hub-type repeaters of the present invention have the advantage that they are simpler and less expensive than previously known hub-type repeaters which are arranged for multiway regeneration. Further they have the advantage, because of the relatively few and inexpensive elements employed in the control circuit, that they can be employed for operation either with or without multiway regeneration at different times. By this is meant that the control circuit of the present invention provided for use when a regenerative repeater is required is so inexpensive that the circuit is adapted to serve also when a regenerative repeater is not required. Formerly so many expensive elements were required in the control circuit when a regenerative repeater was employed with a hub circuit that this was not feasible.

The repeaters of the present invention have the further advantage that when used without multiway regeneration no control relay is required. In one embodiment of the invention no control relay is required for either service. In another embodiment of the invention a single control relay is required for multiway regeneration only.

A feature of the invention is a control circuit in a multiway regenerator hub-type telegraph repeater which requires no relay or other switching element.

The invention may be understood from the following description when read with reference to the associated drawings in which:

Fig. 1 shows an embodiment of the invention in which a control relay is required for multiway regeneration; and

Fig. 2 shows a second embodiment of the invention in which no control relay is required at any time.

Although the invention is presently incorpo- Embodiment per Fig. 1

The manner in which the circuit per Fig. 1 functions when arranged for multiway regeneration will first be described.

The system shown in Fig. 1 comprises three individual repeaters indicated repeater l, repeater 2, and repeater 3, the individual upper horizontal receiving branch and lower horizontal sending branch of each of which repeaters are interconnected through the common vertical receiving hub and the common vertical sending hub to one of the individual repeating devices shown at the right of Fig. 1. When multiway regeneration is not required the repeating relay I0 is employed and the regenerative repeating device 9 is not employed. For multiway regeneration the regenerative repeating device 9 is employed and the repeating relay [0 is not employed. The apparatus included between the sending and receiving leg in each of the individual repeaters is a control circuit Which is primarily intended to prevent retransmission of signals received from any individual repeater back through the sending leg of the same repeater The control circuit may be arranged by means of switches to func tion in two different manners for the two conditions. and 4 in repeater I, and corresponding switches in repeaters 2 and 3, will be closed. Switches 5 and B which connect the regenerative repeater 9 to the concentration of individual repeaters will also be closed. Switches I and 8 will be open.

Assuming switches 2, 4, 49, 8|, 5|, 83, 5 and 6 in the closed position, the circuit as shown in Fig. 1 is in the idle condition. The idle condition is the same as the marking condition except for the fact that during the first portion of a marking signal element which follows a spacing signal element the armature of the regenerative device 22 will be in engagement with its spacing contact For multiway regeneration switches 2 aesaisei C allel branches at junction H3. The receiving branch continues through resistance l9 to the vertical receiving hub and extends through conductor 2i, switch 6, the top winding of relay 22 and negative battery 23 to ground. A corresponding path may be traced through the receiving branch in each of repeaters 2 and 3 and through the hub 2e and the tonwinding of relay 22 to grounded negative battery 23 Although but three repeaters are shown it is to be under.. stood that ordinarily more than three individual repeaters may be connected to the hub. Attention is called to the fact that in each repeater negative battery, such as battery H, is connected to the marking contact of the receiving relay and, negative battery 23 is connected to the top winding of relay 22. The magnitude of the. potential of all of these batteries is the same, so that no current flows in any of the receiving branches or through the top windin of relay 22 for this condition. The armature of'relay '22 is maintainedin engagement with its marking contact 24 under the influence of its biasing circuit which extends from negative battery 23' through the bottom winding of'rela y 22 and resistance 25 to ground. From junction 15 a circuit branch extends through dry. rectifier 23 to junction 2? from which point the. circuit extends through resistance: '23 to junction 33 in the sending leg 3 i. From junction 2'! a branch extends through switch 2 and resistance 5 to open contact l? of relay 33. From junction 8 a circuit branch may be traced through switch 4, resistance 32 anfdgthe top winding of relay 33 to common con ductor 3%," 'A corresponding branch may be traced in e aeh of repeaters 2; and 3 to common conductor 34. A circuit may be traced from negative battery 35; throughjesistance 36, junction 3?, resistance 38, contact 39, armature '43 of relay 33, resistance 41'; and positive battery 42 to ground. From junctionf3l a branch extends through the bottom winding of relay 33toground. No current can flow through the top winding of relay 3.5%, or the top winding of the corresponding relays l t and 46 in each of the other rep-eaters for this condition, since negative batteries '0: the same magnitude are connected to each of the branches or the circuit which extends through each top winding. The magnitudes of the resistances' fi fi, Bfiand ll, and of batteries 35 and 42, are s ochosen that a positive potentialisapplied through the bottom winding of relay 33 between junction 3 and ground and the efiect of thev current flowing through the bottom winding is suchjasto maintainthe armature of relay 3? Corresponding in engagement with contact 3,). conditions prevail in relays t4 and lfi inrepeaters 2 and 3.

When. the armature of relay 22 in regenerative repeater 9-is in engagement with its marking contact. 2fl ,'a circuit may be traced from positive bat-, tery 48 through resistance 59, contact 24, armature f relay 22, and switch 5 to the common.

vertical transmitting hub 52 which is joined in parallel tosending legs 3|, 54 and 5fi; Sending leg 3 extends through resistance 58, junction 30 and the winding of sending relay 60 to ground. Sending legs 54 and 55 extend through corresponding paths in repeaters 2 and.3.respective ly.

The'effect of the current flowin from positive battery through the winding of sending relay 60 maintains I the armature of relay 60in engagement with its marking contact 62. The sending relays .42mi i r similar ntmll d o at.

their armatures are in engagement with their to transmit toward the hub.

marking contacts 68 and 16, respectively, for this condition.

Attention is called to the fact that dry rectifier 26 is so poled that the current from negative battery H cannot pass through the rectifier. Further since contact ll is open, the sending relay 68] is under control solely or the positive battery 43 furnished from the regenerativegrepeater. The same is true of'sehding relays 63 and 62.

It will be assumed that repeater I now starts in response to the first spacing. signal impressed on relay it, its armature 13, will be actuated to engage with its spacing contact]it. Positive battery ll will therefore be impressed through resistance 72 and contact iii on the receiving branch of the repeater l and through the top. winding of relay 22 in the regeneratiye repeater. Positive battery H will therefore be connected in series with negative battery 23. In response to this the armature of relay 22 will be actuated to engage with its spacing contact 73 and j gative battery it" will be impressed through resistance l5, contact 73' andthe armature of relay 22 through switch 5 to sending hub 52, which connects in parallel through the windings of sending relays 6B, 63 and 64; In the case of relays 63 and 64 the armatures of these relays will be actuated to engage withtheir spacing contacts to transmit the spacing signal over their respective sending lines to the distant stations. In the case of repeater I it is necessary that the spacing signal should not be transmitted by relay 6;}, since this would result in the retransmission of a signal received from the same repeater, repeater I.

The manner in which the spacing signal is prevented from being retransmitted by relay 60'- will now be explained.

When in response to the received spacing sig nal in repeater l, positive battery it isimpressed onjunc-tion it, current passes through dry rectifier 26; resistance 2% and the winding of relay 8D to ground. The effect of this current maintainsthe armature of relay 68 in engagement with its marking contact. As is Well known in the art, the regenerative repeater s introduces a; delaybefore it retransmits a signal impressed thereon. This is necessary in order that the-middie or best portion of each received signal element may be sensed by the regenerative repeater-to determine the nature ofthe signal element which is retransmitted. Relay 6%) is placed under-the influence of spacing battery H before the regenerated spacing signal from negative battery E lis, impressed-on sending leg St. The magnitudes .ofresistances 28 and 58 are so chosen that when positive battery it andnegative battery 14- areapplied through their respective branches. on junction 39, a positive potential is impressed between junction wand-ground through the winding of the sending relay 99, Therefore the spacing signaltransmitted-from battery M' when it arrives in sending leg 31, is ineffective tooperate sending relay tii'to spacing.

Attention was called heretofore to the fact that while the markingconditionprevailed no current 'winding of relay 33, conductor 34 and in parallel through the top windings of relays 44 and 46, through resistances 80 and 82, switches 8| and 83, armatures of receiving relays 84 and 66, marking contacts 88 and 90 and resistances 92 and 94 to negative batteries 96 and 98, respectively. The effect of this current flowing through the top winding of relay 33 actuates its armature 46 to engage with its contact 41. When armature 46 breaks from contact 33, the direction of the flow of current through the bottom winding of relay 33 is reversed and its effect is such as to au ment the effect of the current in the upper winding of relay 33, so that the armature 46 is maintained securely in enga ement with contact 41. When armature 46 engages with contact 41' positive battery 42 is impressed through resistance 4|, armature 46, contact 41, resistance 45 and switch 2 on junction 21, so that positive battery. H and positive battery t2 are connected in parallel through resistance 28 and the winding of sending relay 63.

When relay I4 is again actuated to engage with its marking contact, dry rectifier 26 prevents the passage of current from negative battery II. However, positive battery 42 remains effective to maintain sending relay 60 on its marking contact.

When in response to succeeding marking signals, negative battery I I is impressed on junction I8, the flow of current through the top winding of relay 33 ceases. However, the armature 46 of relay 33 is maintained in engagement with its contact 41 by the effect of current flowing through the bottom winding of relay 33. So as long as transmission continues from relay I4 in repeater I, towards the regenerative repeater, the armature 4!! of relay 33 will remain in engagement with its contact 41 and the sending relay 60 in repeater I will be maintained in engagement with its marking contact.

If relay I4 ceases to transmit toward the regenerative repeater, relay 33 will remain locked with its armature 40 in engagement with its contact 41 to continue to maintain the armature of sending relay 66 on marking.

If the receiving relay, such as relay 84, in another repeater, such as repeater 2, starts to transmit toward the regenerative repeater, it is necessary to unlock relay 33, that is assuming that repeater I was the last to transmit toward the regenerative repeater, in order that the first signal element received by relay 84 may be transmitted by the sending relays in each repeater, other than sending relay 63 in repeater 2, including sending relay 60 in repeater I. The manner in which relay 33 is unlocked is as follows:

When the armature of relay 84 engages with its spacing contact I60, positive battery I62 is connected through resistance I04, contact I60, armature of relay 84, switch 8|, resistance 80 and the top winding of relay 44 to vertical conductor 34 which connects to parallel branches. One branch extends through the top winding of relay 33, resistance 32 and switch 4 to negative battery II, connected to the marking contact of relay I4. The other branch extends through a corresponding circuit in repeater 3. The effect of current flowing through the winding of relay 33 in this direction will actuate the armature 46 to engage with contact 39. This removes the look from relay 60 before the first regenerated signal is receivedfrom the regenerative repeater.

'Withrespect to the efiect of current flowing through the top winding of relay 46 in the circuit last traced it will be in a direction to maintain the armature of relay 46 more securely in engagement with its lower contact so that the send- 5 ing leg of repeater 3 will remain unlocked. With respect to relay 44 in repeater 2, it will function in the same manner as described for relay 33 in repeater I when relay I4 started to transmit toward the regenerative repeater, placing a locked marking condition on relay 63 so as to prevent the retransmission of signals, now assumed incoming through relay 84 in repeater 2, back through sending relay 63 in the same repeater.

When a regenerator is not required in the embodiment per Fig. 1 switches 5 and 6 are open. Switches 1 and 8 are closed. Switches 2 and 4 are opened to disconnect a portion of the control circuit in repeater I. Switches 49 and 8|, SI and 83 corresponding to switches 2 and 4, respectively, in each of repeaters 2 and 3 are also opened.

For the marking condition the armature of polar telegraph relay It will be actuated to engage with its marking contact IOI under the influ'ence of current flowing from negative battery no through the lower winding of relay I0 and resistance III to ground. No current will flow through the receiving branch of any of repeaters I, 2 or 3 or through the top winding of relay I0 since battery of the same olarity and magnitude is connected to the marking contact of relays I4, 84 and 66 and to the top winding of relay Ill. Sending relays 60, 63 and 64 will be maintained in their marking condition by the effect of current flowing from positive marking battery II5 through resistance II6, contact IIII, armature of relay l4 and switch 1, which connects to sending hub 52 from whence the sending legs 3|, 54 and 56 in each of repeaters I, 2 and 3, respectively, extend through resistances 58, I26 and I28 and the windings of sending relays 60, 63 and 64, respectively, to ground.

, No current flows in any individual repeater through the branch corresponding to that be tween junctions l6 and 36 in repeater I for the marking condition, for as explained heretofore the dry rectifier such as rectifier 26 in repeater I does not pass current when its upper terminal is negative with respect to its lower terminal.

It will again be assumed that relay I4 in repeater I starts to transmit. When the armature I3 of relay I4 is actuated to engage its spacing contact 16 positive battery H is connected through the receiving branch of repeater I, hub 20, switch 8 and the top winding of relay II] to negative battery, actuating the armature of relay II] to engage with its right-hand or spacing contact. As a result of this negative battery II2 is impressed through resistance H3, contact H4, armature of relay I0, switch 1, sending hub 52, 60 through the sending legs, on the windings of the sending relays 66, 63 and 64. Relays 63 and 64 respond to repeat the spacing signal over their respective connected lines. However, relay 60 is prevented from responding by current which 55 flows from positive battery 1I through the branch between junctions I6 and 30 and through the winding of relay 66 to ground, which maintains relay 6B in the marking condition, the junction 30 as heretofore explained being maintained posi 70 tive for this condition by a proper choice of resistance and potential values.

Attention is called to the fact that when a regenerative repeater is notrequired no appreciable delay is introduced by the repeating device I0.

On a transition from spacing to marking of the armature I3 of relay "I 4 fo'rinstance the armatu'reof relay It is actuate'd almost instantlyirom its spacing to its markingcontact under the influence of its biasing winding which becomes effective the instant armature l3 separates from its spacing contact and during its transition to its marking contact. The interval during which negative spacing battery H2 remains applied through sending branch 3| to the winding of relay 50 after armature 13 leaves its "spacing contact 10 is therefore negligibly short, too short forthe "false operation of relay 60 to spacing. For this reason a single dry rectifier and a resistance in the branch between the junctions l8 and are all that are needed to effect the control function when regeneration is not required.

The reason a control circuit containing additional elements is required in the embodiment per Fig. 1 for regenerative "service is because of the delay, mentioned above, introduced by the regenerative repeater. There is an interval, equal to approximately one-half the duration of a spacing signal element, during which negative spacing potential 74 is required to be applied by the regenerative repeater 9 for the completion of transmission of --a spacing signal element. It for instance relay i4 is receiving and the reception of a spacing signal has just been "completed, the armature I3 will be actuated to its marking contact in response to the first portion of the following marking si'gnal element. The regenerator will continue to transmit a negative s acing "signal element for the delay interval. This would be unopposed since the negative marking battery from relay M would be ineii'ective. This accounts for the necessity for the additional features described in the foregoing for inultiway regene'rator operation in the em bodiment per Fig. 1.

Embodiment .per 2 Refer now to Fig. 2. Fig. 2, like Fig. 1, may be arranged for use with or without in'ulti'way regeneration. In either case no electromag'net or other type relay or switching element is required in the control circuit individual to each repeater.

Fig. 2 is in certain respects similar to Fig. 1. It shows three individual repeaters numbered repeaters 4, 5 and 6 connected through a sending and receiving hub which hubs may be connected by means of switches either to a regenerative repeater 200 or to a polar telegraph relay repeater 263. When the system is to befa'rranged for multiway regeneration switches? and 22 are closed to connect the regenerative repeater and switches '26! and 262 are opened. Switches 23!, 2 and 258 in repeaters 2, 5 and 6, respec tively, are closed so as to connect ca'pacitances 24!, 275 and 216 in circuit. These capacitances are not required except for m'ult'iway regeneration operation. Although but three individual repeaters, repeaters 4, 5 and B, are shown, it is to be understood that ordinarily a larger numher will be employed.

When the designated switches are closed the system of Pig. '2 is in the idle condition which, as heretofore explained for Fig. 1, is the same as for marking except that, when a marking signal element follows a spacing signal element, be cause of the delay introduced by the regenerative repeater 200, the regenerating device 2M will be delayed for the duration of half a signal element before it assumes its marking position as shown. As a result of this in cases wherein a marking signal element follows a spacing signal element the armature of relay 2 will remain in engagement with its spacing contact 2-22 for the first portion of the signal element and will not engage its marking contact 22I nntil after this period has elapsed. For the idle and mm ing condition the armatures 'of each of relays 28?, 250 and 252 will be in engagement with their right -hanol or marking contacts as shown. will connect negative battery irom each, such as negative battery 20!, in repeater 4, through resistance 292, marking contact 283, conductor 2'08 and resistance '21!) to the vertical receiving hub 2H which interconnects all of the receiving branches. From hub 21! the circuit extends through conductor 2i2, switch 213 and the top winding of relay 2M in regenerative repeater 280 to negative battery 2|5. Thus negative battery in each receiving branch is connected in parallel through the top winding of relay 2 to negative battery and no current flows in any branch or through the top winding of relay 2. The armature of relay 2M is maintained in engagement with its marking contact 22! under the influence of current flowing from negative battery 2'15 through the bottom winding of relay 2 i land resistance 216 to ground.

A circuit may also be traced from positive marking battery 2|! through resistance ZIB, marking contact 221, armature of relay 2I '4, conductor 223 and switch 224 to vertical sending hub 225 which is connected to the three sending branches in the three repeaters in parallel. The branch in repeater 4 extends through eonductor 2'2'6, resistance 22'! and the "winding of sending i elay 229 to ground. A corresponding sending branch may be traced in each of repeaters 5 and 6. The efiec't of the current in each of the sending branches maintains the armature of the sending relay in each repeater, such as relay 229 in repeater 4, in engagement with its marking contact, such as contact 230.

Each of repeaters 4, '5 and 6 has a silnilar control circuit. That in repeater comprises a branch interconnecting junction 209 in the receiving leg to junction 228 in the sending leg and a condenser rectifier resistance timing circuit which connects to junction '233. The circuit may be traced from junction 269, through dr'y rectifier 232 and resistance 234 to junction 22%. A branch oi this circuit extends from grounded positive battery 23% through resistance 23'! to junction 233. Another branch of this circuit extends from junction 233 to three parallel branches. The first of the three parallel branches extends through dry rectifier 240 to ground. A second branch extends through switch 23| and condenser 26! to ground. The third branch extends through resistance 24 3 and negative battery 244 to ground.

The dry rectifiers, such as re't'iiiers 232, do not pass current from negative battery so that when the armature of any receiving relay such as relay 207 is in the marking condition, as shown, the negative battery connected to its marking contact has no influence on the sending relay in the same repeater.

It will now be ass'uined that the armature of relay Bill is actuated to engage with the spacing contact. In response to this, positive battery 204 is connected through resistance 2 05 and the spacing contact and armature of relay 201. The eiTe'ct of this current, after the usual regener ator delay interval, actuates the armature of relay 214 to its spacing contact 2 22. This (3611* neots negative battery 22!! through resistance 2!!! and the spacing contact 222 and armature of relay 2M. Relays and 253 will follow this signal each being actuated to its respective spacing contact to transmit a spacing signal over the line connected thereto. It is important, for reasons which should be apparent from the foregoing, that relay 229 should not respond to this signal and that its armature should remain in engagement with its marking contact throughout the interval while repeater 4 is transmitting toward the hub. How this is achieved will now be explained.

As in the embodiment per Fig. 1, when positive battery is applied to the top terminal of the dry rectifier in a control circuit, such as dry rectifier 232, current flows freely through it and through resistance 230, junction 228 and the winding of sending relay 229. The polarity of junction 228 becomes positive almost instantly and, due to a choice of resistance values, the positive polarity is maintained even after the armature of relay 2M engages its spacing contact 222 and negative battery 22a is impressed on the sending leg. During the spacing interval of relay 207 the left hand plate of condenser 24! is charged positively substantiall to the potential of battery 204. After the end of the spacing signal interval of relay 201, the armature 205 will again be actuated to engage its marking contact 203. The armature of relay 234 in regenerative repeater 200 will remain in engagement with its spacing contact 222 during the delay interval. It is necessary to maintain the armature of relay 229 on its marking contact during this delay interval. This is performed by the discharge of condenser 24! through the winding of relay 229. Dry rectifier 240 is so poled that it does not pass current from positive battery 204, permitting the left-hand plate of condenser 24! to build up, as 1 mentioned, substantiall to the positive potential of battery 204. Once the positive potential source 204 is disconnected condenser 24! starts to discharge through two parallel paths comprising resistance 243 to negative battery 244 and reristance 234, winding of relay 229 to ground. The current voltage discharge characteristic curve of a condenser when discharging from say a positive voltage to ground, as is well known, has an inclined substantially 'straight line portion during which the current decreases at a substantially constant rate as the voltage decreases and then the curve flattens while the current falls more slowly as the voltage decreases. When a condenser which is charged to a certain level by a potential of one polarity discharges to a potential of the opposite polarity the current voltage curve does not flatten but remains at a substantially constant pitch as the potential of he condenser approaches ground potential. The ground 245 acts, through rectifier 220, as a limiter. When the left-hand terminal of condenser 24! reaches ground potential the discharge or" the condenser ceases. The capacitance of the condenser and the magnitude of the resistances and potentials are so chosen that relay 22%: is maintained on its marking contact during a fixed predetermined delay interval on a transition from spacing to marking and until the effect of positive battery 2!! applied to the marking contact of relay 2 !4 in the regenerative repeater becomes efiective to maintain the armature of relay 229 in the marking condition.

The function of positive battery 236 connected through resistance 23'! to junction 238 is to com.-

pensate for the biasing effect of battery 244 on relay 229. During the actuation of relay229 by signals originating at relay 250 or relay 252, a marking current is supplied to junction 228 by battery 236 through resistance 23? which is equal in magnitude to the spacing current which is supplied to junction 228 b battery 244 through resistances 243 and 234. Consequently, relay 229 is permitted to faithfully reproduce the signals impressed on it by regenerative repeater 200.

When a regenerator is not required in the embodiment per Fig. 2, switches 2!? and 224 are opened. Switches 26! and 262 are closed. Switches 231, 235 and 250 are opened in each'of th individual repeaters.

Under this condition relay 263 functions in a manner corresponding to that of relay !0 in Fig. 1. In response to signals incoming through the receiving relay such as relay 20'! in any individual repeater such as repeater 4, relay 263 will impress the signals on the sending relays such as 25! and 253 in the individual repeaters which will follow and retransmit the signals. There will be no appreciable delay. The sending rela such as relay 229 must not follow the signals received from its own repeater, and willbe maintained in the marking condition by positive battery 268 during marking intervals.

During spacing intervals the efiect of positive battery such as battery 204 through the control branch between terminals 209 and 228 will be dominant over negative battery 266 on the spacing contact of relay 253 to maintain the armature of relay 229 in the marking condition.

It will be understood, however, that optionally switches 23!, 235 and 260 may be left closed when a regenerator is not used. In this case the holding effect of condensers 2.4!, 215 and 216 will serve to insure that the sending relay of a repeater which is receiving signals from the line will be maintained in the marking condition, even if rela 263 should be slow in returning from the spacing to the marking condition.

What is claimed is:

1. In a telegraph system, an individual hubtype repeater, a receiving relay connected to a receiving leg, a sending relay connected to a sending leg and a control circuit interconnecting said legs, for preventing retransmission by said sending relay of signals received through said receiving relay, sources of potential of opposed polarities connectable to the armature of said receiving relay for the transmission of marking and spacing signal elements, said control circuit consisting of a potential polarity sensitive shunt interconnecting said legs to control said sendin relay during the transmission of one or the other of said marking or said spacing signal elements.

2. In a telegraph system, an individual hubtype repeater, a receiving rela connected to a receiving leg, a sending relay connected to a sending leg, a control circuit interconnecting said legs for preventing retransmission by said sending relay of signals received by said receiving leg, said control circuit having a potential polarity sensitive shunt and a, condenser discharge delay circuit connectable to said shunt to prolong the interval of control of said sending relay when required.

3. In a telegraph system, an individual hubtype repeater having a receiving relay connected through an individual receiving leg and a common receiving hub and a sending relay connected through an individual sending leg and a common sending hub, each of said hubs flexibly connectable to a relay repeater at a first time and to a regenerative repeater at a second time, a control circuit directly interconnecting said legs, to prevent retransmission by said sending relay of signals received by said receiving relay, a group of control elements, and flexible switching means in said control circuit for adding said elements to or subtracting said elements from said control circuit to arrange said hub-type repeater for effective operation at said first and said second times.

4. In a telegraph system, at least two individual repeaters, a single repeater common to said individual repeaters, a receiving leg and a transmitting leg in each of said individual repeaters interconnected to said single repeater through a common receiving hub and a common transmitting hub, means in each one of said individual repeaters for efiectively transmitting from any one of said individual repeaters at a particular time through said receiving hub said single repeater and said transmitting hub to all of the other of said individual repeaters simultaneously, an individual potential polarity sensitive shunt control circuit connected directly between said receiving leg and said sending leg in each of said individual repeaters for preventing retransmission of signals originating in any one of said individual repeaters back through the same individual repeater in which the signals .are originating.

5. A system in accordance with claim 4, said system including additional elements in said control circuit to prevent said retransmission when said single repeater is a regenerative repeater.

6. A system in accordance with claim 4, said system including additional elements in each of said control circuits to prevent said retransmission when said single repeater is a regenerative repeater, said elements includingnot more than one relay individual to each of said control circuits, a winding on each of said relays, said winding connected individually to its associated receiving leg, and a commonconnection connecting each of said windings in parallel.

'7. Ina telegraph system, at least two individual repeaters, a single repeater common to said individual repeaters, a receiving leg and a transmitting leg in each of said individual repeaters interconnected to said single repeater through a common receiving hub and a common transmitting hub, means. in each one of said individual repeaters for effectively transmitting from any one of said individual repeaters at a particular time through said receiving hub said single repeater and said transmitting hub to all of the other of said individual repeaters simultaneously, an individual potential polarity sensitive shunt control circuit connected directly between said receiving leg and said sending leg in each of said individual repeaters for preventing retransmission of signals originating in any one of said individual repeaters back through the same individual repeater in which the signals are originating, said system including additional elements in said control circuit to prevent said retransmission when said single repeater is a regenerative repeater, said additional elements consisting of a condenser, a potential polarity sensitive element, resistors and sources of potential.

WILTON T. REA.

REFERENCES CITED UNITED STATES PATENTS Name Date Hanley Nov. 16, 1943 Number 

